Foot-and-mouth disease virus 3A hijacks Sar1 and Sec12 for ER remodeling in a COPII-independent manner

Positive-stranded RNA viruses modify host organelles to form replication organelles (ROs) for their replication. Enteroviral 3A protein has been demonstrated to be highly associated with the COPI pathway, in which factors work on the ER-to-Golgi intermediate and the Golgi. However, Sar1, a COPII factor exerting coordinated action at endoplasmic reticulum (ER) exit sites, rather than COPI factors, is required for foot-and-mouth disease virus (FMDV) replication. Therefore, we thought that deep understanding of FMDV 3A was the key to explaining the differences and to unlocking the secret of FMDV RO formation. In this study, FMDV 3A was confirmed as a peripheral membrane protein capable of modifying the ER into vesicle-like structures, which were neither COPII vesicles nor autophagosomes. When the C-terminus of 3A was truncated, it would be located at the ER without vesicular modification. This change was revealed by mGFP and APEX2 fusion constructs observed by fluorescence microscopy and electron tomography, respectively. Referring to other 3A truncation, the minimal region for modification was aa 42–92. Furthermore, we found that the remodeling was related to two COPII factors, Sar1 and Sec12. Both interacted with 3A, but their binding domains on 3A were different. Finally, we hypothesized that the N-terminus of 3A would interact with Sar1 as its C-terminus simultaneously interacted with Sec12, which possibly would enhance Sar1 activation. On the ER membrane, two active Sar1 were connected by 3A with regions of aa 42–59 and aa 76–92, causing curvature of the membrane. This mechanism is distinct from the traditional COPII pathway and should be crucial for FMDV RO formation.

Ionophore-stimulation promotes re-organization of the invasion machinery of Toxoplasma gondii

Host cell invasion by intracellular, eukaryotic parasites, like the many important species within the phylum Apicomplexa, is a remarkable and active process involving the coordinated action of many apical organelles and other structures. To date, capturing how these various structures interact during invasion has been difficult to observe in detail. Here, we used cryogenic electron tomography to generate images of the apical complex of Toxoplasma gondii tachyzoites under conditions that mimic resting parasites and those primed to invade through addition of a calcium ionophore. Using AI-based image-processing we were able to annotate 48 tomograms to identify and extract densities of the relevant subcellular organelles and accurately analyze features in 3D. We describe an interaction between an anteriorly located apical vesicle and a rhoptry tip that occurs only in the ionophore-stimulated parasites and that is associated with dramatic changes in the vesicle's shape in what appears to be a stalled fusion event. We also present information to support the presumption that this vesicle originates from the well-described vesicles that parallel the intraconoidal microtubules and that the latter two structures are linked by a novel tether. Lastly, we show that a previously described rosette is found associated with more than just the anterior-most apical vesicle, indicating that multiple such vesicles are primed to enable rhoptry secretion.

In situ structure and priming mechanism of the rhoptry secretion system in Plasmodium revealed by cryo-electron tomography

Apicomplexan parasites secrete the contents of rhoptries into host cells to permit their invasion and establishment of an infectious niche. The rhoptry secretory apparatus (RSA), which is critical for rhoptry secretion, was recently discovered in Toxoplasma and Cryptosporidium. It is positioned at the cell apex and associates with an enigmatic apical vesicle (AV), which docks one or two rhoptries at the site of exocytosis. The interplay among the rhoptries, the AV, and the parasite plasma membrane for secretion remains unclear. Moreover, it is unknown if a similar machinery exists in the deadly malaria parasite Plasmodium falciparum. In this study, we use in situ cryo-electron tomography to investigate the rhoptry secretion system in P. falciparum merozoites. We identify the presence of an RSA at the cell apex and a morphologically distinct AV docking the tips of the two rhoptries to the RSA. We also discover two new organizations: one in which the AV is absent with one of the two rhoptry tips docks directly to the RSA, and a second in which the two rhoptries fuse together and the common tip docks directly to the RSA. Interestingly, rhoptries among the three states show no significant difference in luminal volume and density, suggesting that the exocytosis of rhoptry contents has not yet occurred, and that these different organizations likely represent sequential states leading to secretion. Using subtomogram averaging, we reveal different conformations of the RSA structure corresponding to each state, including the opening of a gate-like density in the rhoptry-fused state. These conformational changes of the RSA uncover structural details of a priming process for major rhoptry secretion, which likely occur after initial interaction with a red blood cell. Our results highlight a previously unknown step in the process of rhoptry secretion and indicate a regulatory role for the conserved apical vesicle in host invasion by apicomplexan parasites.

Adeno-associated Virus Receptor-binding: Flexible Domains and Alternative Conformations through cryo-Electron Tomography of AAV2 and AAV5 complexes

Recombinant forms of adeno-associated virus (rAAV) are vectors of choice in the development of treatments for a number of genetic dispositions. Greater understanding of AAV's molecular virology is needed to underpin needed improvements in efficiency and specificity. Recent advances have included identification of a near universal entry receptor, AAVR, and structures by cryo-electron microscopy (EM) single particle analysis (SPA) that revealed, at high resolution, only the domains of AAVR most tightly bound to AAV. Here, cryogenic electron tomography (cryo-ET) is applied to reveal the neighboring domains of the flexible receptor. For AAV5, where the PKD1 domain is bound strongly, PKD2 is seen in three configurations extending away from the virus. AAV2 binds tightly to the PKD2 domain at a distinct site, and cryo-ET now reveals four configurations of PKD1, all different from that seen in AAV5. The AAV2 receptor complex also shows unmodeled features on the inner surface that appear to be an equilibrium alternate configuration. Other AAV structures start near the 5-fold axis, but now β-strand A is the minor conformer and, for the major conformer, partially ordered N-termini near the 2-fold axis join the canonical capsid jellyroll fold at the βA-βB turn. The addition of cryo-ET is revealing unappreciated complexity that is likely relevant to viral entry and to the development of improved gene therapy vectors. IMPORTANCE: With 150 clinical trials for 30 diseases underway, AAV is a leading gene therapy vector. Immunotoxicity at high doses used to overcome inefficient transduction, has occasionally proven fatal and highlighted gaps in fundamental virology. AAV enters cells, interacting through distinct sites with different domains of the AAVR receptor, according to AAV clade. Single domains are resolved in structures by cryogenic electron microscopy. Here, the adjoining domains are revealed by cryo-electron tomography of AAV2 and AAV5 complexes. They are in flexible configurations interacting minimally with AAV, despite measurable dependence of AAV2 transduction on both domains.

UVC inactivation of pathogenic samples suitable for cryo-EM analysis

Cryo-electron microscopy has become an essential tool to understand structure and function of biological samples. Especially for pathogens, such as disease-causing bacteria and viruses, insights gained by cryo-EM can aid in developing cures. However, due to the biosafety restrictions of pathogens, samples are often treated by chemical fixation to render the pathogen inert, affecting the ultrastructure of the sample. Alternatively, researchers use in vitro or ex vivo models, which are non-pathogenic but lack the complexity of the pathogen of interest. Here we show that ultraviolet-C (UVC) radiation applied at cryogenic temperatures can be used to eliminate or dramatically reduce the infectivity of Vibrio cholerae and the bacterial virus, the ICP1 bacteriophage. We show no discernable structural impact of this treatment of either sample using two cryo-EM methods: cryo-electron tomography followed by sub-tomogram averaging, and single particle analysis (SPA). Additionally, we applied the UVC irradiation to the protein apoferritin (ApoF), which is a widely used test sample for high-resolution SPA studies. The UVC-treated ApoF sample resulted in a 2.1 Å structure indistinguishable from an untreated published map. This research demonstrates that UVC treatment is an effective and inexpensive addition to the cryo-EM sample preparation toolbox.

Exploring high-resolution cryo-ET and subtomogram averaging capabilities of contemporary DEDs

The potential of energy filtering and direct electron detection for cryo-electron microscopy (cryo- EM) image processing has been well documented for single particle analysis (SPA). Here, we assess the performance of recently introduced hardware for cryo-electron tomography (cryo-ET) and subtomogram averaging (STA), an increasingly popular structural determination method for complex 3D specimens. We acquired cryo-ET datasets of EIAV virus-like particles (VLPs) on two contemporary cryo-EM systems equipped with different energy filters and direct electron detectors (DED), specifically a Krios G4, equipped with a cold field emission gun (CFEG), Thermo Fisher Scientific Selectris X energy filter, and a Falcon 4 DED; and a Krios G3i, with a Schottky field emission gun (XFEG), a Gatan Bioquantum energy filter, and a K3 DED. We performed constrained cross-correlation-based STA on equally sized datasets acquired on the respective systems. The resulting EIAV CA hexamer reconstructions show that both systems perform comparably in the 4-6 Angstrom resolution range. In addition, by employing a recently introduced multiparticle refinement approach, we obtained a reconstruction of the EIAV CA hexamer at 2.9 Angstrom. Our results demonstrate the potential of the new generation of energy filters and DEDs for STA, and the effects of using different processing pipelines on their STA outcomes.

Correlative cryogenic montage electron tomography for comprehensive in-situ whole-cell structural studies

Imaging large fields of view while preserving high-resolution structural information remains a challenge in low-dose cryo-electron tomography. Here, we present robust tools for montage electron tomography tailored for vitrified specimens. The integration of correlative cryo-fluorescence microscopy, focused-ion beam milling, and micropatterning produces contextual three-dimensional architecture of cells. Montage tilt series may be processed in their entirety or as individual tiles suitable for sub-tomogram averaging, enabling efficient data processing and analysis.

Microtubule plus-end regulation by centriolar cap proteins

Centrioles are microtubule-based organelles required for the formation of centrosomes and cilia. Centriolar microtubules, unlike their cytosolic counterparts, grow very slowly and are very stable. The complex of centriolar proteins CP110 and CEP97 forms a cap that stabilizes the distal centriole end and prevents its over-elongation. Here, we used in vitro reconstitution assays to show that whereas CEP97 does not interact with microtubules directly, CP110 specifically binds microtubule plus ends, potently blocks their growth and induces microtubule pausing. Cryo-electron tomography indicated that CP110 binds to the luminal side of microtubule plus ends and reduces protofilament peeling. Furthermore, CP110 directly interacts with another centriole biogenesis factor, CPAP/SAS-4, which tracks growing microtubule plus ends, slows down their growth and prevents catastrophes. CP110 and CPAP synergize in inhibiting plus-end growth, and this synergy depends on their direct binding. Together, our data reveal a molecular mechanism controlling centriolar microtubule plus-end dynamics and centriole biogenesis.

Molecular structures and conformations of protocadherin-15 and its complexes on stereocilia elucidated by cryo-electron tomography

Mechanosensory transduction (MT), the conversion of mechanical stimuli into electrical signals, underpins hearing and balance and is carried out within hair cells in the inner ear. Hair cells harbor actin-filled stereocilia, arranged in rows of descending heights, where the tips of stereocilia are connected to their taller neighbors by a filament composed of protocadherin 15 (PCDH15) and cadherin 23 (CDH23), deemed the ‘tip link’. Tension exerted on the tip link opens an ion channel at the tip of the shorter stereocilia, thus converting mechanical force into an electrical signal. While biochemical and structural studies have provided insights into the molecular composition and structure of isolated portions of the tip link, the architecture, location and conformational states of intact tip links, on stereocilia, remains unknown. Here we report in situ cryo-electron microscopy imaging of the tip link in mouse stereocilia. We observe individual PCDH15 molecules at the tip and shaft of stereocilia and determine their stoichiometry, conformational heterogeneity, and their complexes with other filamentous proteins, perhaps including CDH23. The PCDH15 complexes occur in clusters, frequently with more than one copy of PCDH15 at the tip of stereocilia, suggesting that tip links might consist of more than one copy of PCDH15 complexes and, by extension, might include multiple MT complexes.